A computational model to unravel the function of amyloid-βpeptide in contact with a phospholipid membrane
Pham Dinh Quoc Huy1, Pawel Krupa1, Hoang Linh Nguyen2, Giovanni La Penna3,4*,Mai Suan Li1,2,*
1 Institute of Physics, Polish Academy of Sciences, Warsaw, Poland2 Institute for Computational Science and Technology, Ho Chi Minh City, Vietnam3 Institute for Chemistry of Organometallic Compounds, National Research Council,Florence, Italy4 Section Roma-Tor Vergata of Italian Institute for Nuclear Physics, Roma, Italy
* [email protected]; [email protected]
Abstract
The normal synapse activity involves the release of copper and other divalent cations inthe synaptic region. These ions have a strong impact on the membrane properties,especially when the membrane has charged groups, like it is the case of synapse. In thiswork we use an atomistic computational model of dimyristoyl-phosphatidylcholine(DMPC) membrane bilayer. We perturb this model with a simple model of divalentcation (Mg2+), and with a single amyloid-β (Aβ) peptide of 42 residues, both with andwithout a single Cu2+ ion bound to the N-terminus. In agreement with experimentalresults reported in the literature, the model confirms that divalent cations locallydestabilize the DMPC membrane bilayer, and, for the first time, that the monomericform of Aβ helps in avoiding the interactions between divalent cations and DMPC,preventing significant effects on the DMPC bilayer properties. These results arediscussed in the frame of a protective role of diluted Aβ peptide floating in the synapticregion.
Author summary
We modelled the behavior of a Mg2+ divalent cation, with the size of Zn2+ and Cu2+,in contact with a phosphatidyl lipid bilayer. We also modelled the monomericamyloid-β peptide 1-42, both free and Cu-loaded, the latter mimicking the final step ofthe binding between the peptide and the divalent cation. On the basis of the simulationresults, we propose that the peptide hinders the strong interactions between the divalentcation and the membrane.
Introduction 1
Alzheimer’s disease is a degenerative disease, with one histological hallmark being 2
extracellular deposits in the central nervous system [1]. These deposits are made of 3
amyloid peptides originated by the amyloid precursor protein (APP), a trans-membrane 4
protein with a multimodal function [2]. Amyloid-β (Aβ) peptides are produced with 5
proteolysis of APP at the membrane interface, by the enzymes β and γ-secretases. The 6
γ cleavage, that produces most of the neurotoxic peptides (39-42 residues), occurs 7
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deeper in the membrane bilayer compared to β cleavage [3]. The production of these 8
toxic peptides at the membrane interface can have many important implications [4], 9
even before peptide aggregation occur and when oligomers are more abundant than 10
protofibrils [5, 6]: i) the toxic pathway can be influenced by interactions between 11
peptides and of peptides with the membrane; ii) the peptide, depending on its 12
concentration, can destabilize the membrane, contributing to cell instability and neuron 13
death (apoptosis). Both these effects are eventually exerted in a complex frame, with 14
many molecules present: APP N-terminus (before the cleavage); peptides in monomeric, 15
oligomeric and pre-fibrillar assemblies; other cofactors, like metal ions. Thus, even at 16
the monomer level, the interactions between amyloid peptides and biological membranes 17
are still poorly understood [7]. More complete models are required to contribute to 18
recent views of APP and Aβ, where Aβ aggregation is interpreted as a loss of functional 19
Aβ monomers [8]. 20
Molecular simulations, particularly molecular dynamics (MD), became a standard 21
tool of computational biology to understand molecular interactions in such complex 22
frames [9]. Despite the large number of simulation studies involving Aβ 23
monomers [10,11], oligomers [12,13], and fibril-like assemblies [14–18], with all species 24
in contact with membrane models, the role of cofactors abundant in the environment of 25
neurons have seldom been taken into account [19]. Among these cofactors, divalent ions, 26
and especially copper, are relevant for a correct physiology of the synapse [20]. Some of 27
the known facts are summarized below. 28
1. Copper (Cu) and zinc (Zn) are particularly abundant in the synaptic region, 29
reaching concentrations up to 0.3 mM after functional extracellular release [20–23]. 30
These concentrations are many orders of magnitude larger than that inside the 31
cell, where Cu, for instance, is present in negligible amount as an ion available to 32
interactions [24,25]. The addressing of APP as a copper mediator has been 33
discovered [26] and lately associated to many neurodegenerative disorders [27,28]. 34
2. Divalent cations change membrane structure, transport properties [29–31], and 35
reactivity [32], thus possibly promoting protein aggregates resembling ion channels 36
and membrane pores [33,34]. 37
3. Cu ions in contact with Aβ peptides form catalysts for the production of reactive 38
oxygen species, activating dioxygen molecules [35,36], and promoting oxidative 39
pathways [37–40]. 40
Because of these important issues, the modeling of interactions of divalent cations 41
with lipid charged and zwitterionic membranes is becoming a challenge [41–43]. Indeed, 42
recent accurate models explain the experimentally observed strong interactions between 43
Ca2+ and phosphate groups in POPC bilayers [43]. 44
In this work, we compare, for the first time, models of free and peptide-bound 45
divalent cations in interaction with dimyristoyl-phosphatidylcholine (DMPC) bilayers, 46
with special emphasis on oxidized copper. Polarizable models of interactions between 47
divalent cations and biological macromolecules are still experimental [43]. Even for 48
nucleic acids, the contribution of Mg2+ to the stability of tertiary RNA folding is 49
intricate [44]. Overall, it is not trivial starting from an unbound condition to sample 50
bound conditions that are observed experimentally. Copper binding is known to be 51
fluxional and strongly dependent on the environment [45,46]. Therefore we apply 52
separately two modeling techniques: i) a naive non-bonded model of Mg2+ that has 53
been used to model the free energy change for the exchange reaction between the water 54
solution and a protein [47], and for neutralizing RNA phosphate groups [48]; ii) a 55
bonded model of Cu2+ that has been applied to describe a well documented binding site 56
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for Cu-Aβ(1-42) observed in experiments [49–51] and extensively modelled by MD 57
simulations [36,52]. 58
The models describe interactions between, respectively, Mg2+ aqua-ions, Aβ(1-42), 59
and Cu(II)-Aβ(1-42) monomers with DMPC bilayers, the latter a well studied molecular 60
model of biological membrane. The simple model used for the Mg divalent 61
aqua-ion [47,48] can depict a first approximation of the effects of Cu2+ ions, that have 62
size similar to Mg2+ when not bound to proteins. These effects mimic those of oxidized 63
Cu on the membrane structure when Cu is released in the synapse and not captured by 64
Cu extracellular carriers. 65
The model, investigated by means of multiple conventional MD simulations (CMD, 66
hereafter) and replica exchange MD (REMD), is limited to Aβ monomers and to 67
exogenous addition of Aβ to the lipid membrane, rather than to peptide incorporation 68
into membrane during its assembly (see Methods). This assumption is representative of 69
the functional conditions in the synaptic region, where both Aβ peptides and divalent 70
cations are released, at low concentration, in the synaptic cleft during the normal 71
activity of neurons. Also, in vitro experiments about Aβ-DMPC interactions mediated 72
by divalent cations have been performed mimicking exogenous addition [53,54]. 73
Finally, the role of divalent cations in cell signaling is more general than in 74
synapse [55]. Therefore, it is of utmost importance to understand interactions of 75
divalent cations with neuron membrane in the presence of modulating ions’ ligands. 76
Methods 77
A summary of the simulations performed in this work is reported in Table 1. 78
Table 1. Summary of simulations analyzed in this work. Abbreviations: CMD - conventional moleculardynamics; REMD - replica exchange molecular dynamics; DMPC - dimyristoyl-phosphatidylcholine; Aβ -Aβ(1-42) peptide, charge -3; Cu-Aβ - Cu-Aβ(1-42) complex, charge -2. See Methods for details.
Simulation Composition number of equilibration analysisreplicas/ time (ns) time (ns)
trajectories
DMPC CMD 2×77 DMPC H2O 4 200 200+37 K+37 Cl+13511 H2O
Mg/DMPC CMD 2×77 DMPC +Mg 3 200 200+35 K+37 Cl+13510 H2O
Aβ/DMPC REMD Aβ+2×77 DMPC 56 200 200+39 K+36 Cl+13511 H2O
Cu-Aβ/DMPC REMD Cu-Aβ+2×77 DMPC 56 200 200+38 K+36 Cl+13511 H2O
Aβ/DMPC CMD Aβ+2×77 DMPC 10 500 500+39 K+36 Cl+13511 H2O
Cu-Aβ/DMPC CMD Cu-Aβ+2×77 DMPC 10 500 500+38 K+36 Cl+13511 H2O
Set-up of molecular dynamics simulations 79
The amyloid-β peptide of 42 residues (Aβ(1-42)), with and without a single bound 80
copper ion in 2+ oxidation state (Cu2+), was simulated with constant temperature 81
molecular dynamics (conventional MD, CMD hereafter) and with the replica exchange 82
molecular dynamics (REMD) method, in order to sample the configurational statistics 83
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at the physiologically relevant temperature of 311 K (38◦ C). The peptide and the ions 84
were put in contact with a bilayer composed of 85
1,2-dimyristoyl-sn-glycero-3-phosphocholine (also abbreviated as 86
dimyristoyl-phosphatidylcholine, DMPC hereafter) lipid molecules. 87
The sequence of Aβ(1-42) is: 88
DAEFRHDSGY10 EVHHQKLVFF20 AEDVGSDKGA30 IIGLMVGGVV40 IA 89
with aminoacids indicated with the one-letter code. We used the Amber16 package [56], 90
with the FF14SB [57] force-field for the peptide and monovalent ions (KCl), TIP3P 91
water model [58] for the explicit water solvent, and LIPID14 [59] for the DMPC 92
molecules. AMBER FF14SB force-field is an improved version of FF99SB [60] used in 93
our previous simulations [52, 61]. Although older CHARMM force-fields tend to provide 94
better results for Aβ peptide than old AMBER force-fields [62], new AMBER versions, 95
especially AMBER FF14SB and CHARMM36m provide good agreement with 96
experimental data for Aβ [63, 64]. Moreover, AMBER FF14SB is fully compatible with 97
LIPID14 force-field [59], which is expected to provide optimal accuracy for both lipids 98
and peptide in the simulations. The use of more recent force-fields for IDPs will be 99
pursued in the future, after a detailed comparison between experiments and simulations 100
in generalized ensembles will be reported in the context of amyloid peptides. 101
We assumed the physiological (pH∼7) protonation state for aminoacid sidechains 102
and free termini. Thus, the charge of Aβ(1-42) is -3 (the N-terminus is protonated and 103
the C-terminus deprotonated). The parameters for copper and copper-bound 104
aminoacids were the same used in our previous MD and REMD simulations [52, 61]. Cu 105
is bound to N and O of Asp 1, Nδ of His 6 and Nε of His 13, the latter protonated at 106
Nδ. His 14 is neutral and protonated in Nε, like His 6. 107
Bond distances and angles involving Cu contribute to harmonic energy terms, with 108
stretching constants, bending constants, and equilibrium values set as fitting parameters 109
of quantum-mechanics calculations at the density-functional level of approximation for 110
truncated models (see Methods in [52]). All the dihedral angles where Cu has index 2 or 111
3, do not contribute to the potential energy, while those with Cu with index 1 or 4 are 112
obtained by the AMBER99SB force-field where heavy atoms have the same dihedral 113
indices of Cu. Point charges are derived from the restrained electrostatic potential 114
(RESP) method [65,66], where the electrostatic potential mapped onto the 115
solvent-accessible surface was obtained at the density-functional level of truncated 116
models (see Ref. 52 for details). Excess of net charge, obtained by merging point 117
charges of truncated models into AMBER FF14SB aminoacids, was distributed to Cβ 118
and Hβ of Asp 1, His 6 and His 13 when these residues are bound to Cu2+. 119
Lennard-Jones parameters for Cu are reported in the literature [67]. The Cu2+120
coordination geometry in this empirical force-field is approximately square-planar, with 121
a fifth axial coordination always available to electrostatic interactions, as shown in 122
previous simulations performed with the same force-field [36]. The distance between 123
configurations obtained with this empirical force-field and minimal-energy 124
configurations obtained including explicit electrons (like in density-functional theory 125
applied to truncated models) is small. 126
As for the free divalent cation, we used the so called “dummy” cation model for 127
Mg2+ [47]. This model has been used together with AMBER99SB phosphate 128
groups [48], where it showed reasonable electrostatic properties. Even though this 129
model is a very crude approximation of divalent cations, it is far more reliable than a 130
single site with point charge 2+. A comparison between the affinity of divalent and 131
monovalent cations for the DMPC membrane has been performed by umbrella sampling 132
estimates of free energy differences (see Supporting Information, file ). 133
An initial lattice model of DMPC bilayer was built, using 77 DMPC molecules per 134
layer, with an approximate area per molecule of 62 A2. An orthorhombic simulation cell 135
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was built, with the cell side along zeta, the latter the direction normal to the DMPC 136
layer, initially set to 70 A. The space between the periodic images of the bilayer was 137
filled with 13511 water molecules, initially at the density of 1 g/cm3, according to the 138
TIP3P model of bulk water at room conditions. KCl was added in the same space, 139
according to an approximate bulk concentration of 0.1 M. Ions were added randomly 140
replacing water molecules in the initial configuration. The number of Cl- anions was 141
adapted to the change of net charge due to addition of the peptide (see below). The net 142
charge of the simulation cell was always zero. 143
Initial configurations of amyloid−β monomer, without copper (charge 3-) and with 144
copper (charge 2-, because of N-terminus deprotonation), were inserted in the space 145
filled by the water molecules. The same was done for the single divalent cation. The 146
concentration of divalent cation in this cell is 10 mM, thus in the range of the 147
concentration used for Ca, Mg, Zn and Cu in in vitro experiments. With a few 148
exceptions, in vitro experiments use concentrations, both of peptide and divalent ions, 149
about 2 orders of magnitude larger than in vivo in the synaptic region of CNS neurons 150
(∼10-100µM). 151
To remove eventual bad contacts produced by each initial configuration set-up, we 152
performed 25000 steps of steepest decent energy minimization, followed by other 25000 153
steps of conjugate gradient energy minimization. 154
The initial coordinates for the CMD and REMD simulations are included as 155
Supporting Information in the protein data-bank (PDB) file format (the first 156
configuration) and as compressed (Bzip2) XYZ format. See , , , , , and . 157
Molecular dynamics simulation protocol 158
We simulated MD trajectories in the isobaric-isothermal (NPT) statistical ensemble, at 159
the constant temperature of 311 K and at the pressure of 1 Atm. Temperature was 160
controlled by a Langevin thermostat [68] with collision frequency of 2 ps−1. Pressure 161
was controlled by a stochastic barostat, with relaxation time of 100 fs. The SHAKE 162
algorithm [69] was applied to constrain bonds involving hydrogen atoms. A cut-off of 163
10 A was applied for non-bonded interactions and the particle mesh Ewald 164
algorithm [70] was used to compute long-range Coulomb and van der Waals interactions. 165
The simulation time-step was 2 fs. 166
In order to increase the sampling, we collected several trajectories for each system, 167
starting from different initial conditions, that is the initial velocities (DMPC) and the 168
position of the solute within the water layer (other systems). Composition of each 169
system and some parameters related to sampling are reported in Table 1. 170
Replica-exchange molecular dynamics simulation 171
The REMD simulation was carried out with 56 replicas (or trajectories) corresponding 172
to 56 temperatures ranging from 273K to 500K. The minimized structure was 173
distributed among 56 replicas, and each replica was equilibrated in 200000 steps at the 174
temperature chosen in the temperature distribution. After equilibration, the replica 175
exchange molecular dynamics simulation started, lasting a total time of 400 ns. The 176
exchange of temperature between pair of replicas was attempted every 500 steps of 177
simulation. The REMD simulation is used here mainly to capture the statistical 178
contribution of extended peptide configurations and partially disordered layers, 179
configurations that are rarely sampled at temperatures in the range where the 180
force-field is accurate. The acceptance rate of REMD simulations was, on average, 20% 181
and 21% for, respectively, Aβ(1-42) and Cu-Aβ(1-42). 182
The behavior of lipid order parameters as a function of temperature (data not shown 183
here) shows that the DMPC bilayer is, at the temperature closest to that of the human 184
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body (37◦ C, 310 K), in the liquid crystalline phase. The configurations sampling the 185
temperature of 311 K are, therefore, analyzed in detail in the following. 186
To avoid possible bias due to initial configuration construction, we used 187
approximately the second half of each simulation for analysis (see Table 1). 188
Analysis 189
Structural properties 190
Root-mean-square deviation (RMSD) and radius of gyration (Rg) were calculated for all 191
Aβ(1-42) atoms using the initial Aβ(1-42) structure as a reference for the RMSD 192
measurement. Secondary structure of Aβ(1-42) was analyzed using DSSP software 193
included in the cpptraj tool [56], a part of AmberTools package. Three regular types of 194
secondary structure were distinguished in the analysis: helices (α, 3-10, and π), β-sheets 195
(parallel and antiparallel), and turns, while the residues in other conformations were 196
treated as unstructured (coil). Solvent accessible surface area was calculated for 197
Aβ(1-42) and lipids using Linear Combinations of terms composed from Pairwise 198
Overlaps (LCPO) method [71], implemented in cpptraj. 199
Radial distribution function (RDF) measures the probability to have the distance 200
between two sites within a given distance range, N(r). As usual for liquids and 201
polymers, this quantity is then divided for the same probability for the ideal gas with 202
the same uniform density of sites, Nid(r): g(r) = N(r)/Nid(r). The function g(r) 203
approaches the limit g(r) =1 when r →∞, i.e. when the two sites in the pair become 204
not correlated. 205
The bilayer thickness is defined as the distance between the two planes formed by 206
phosphor atoms belonging to each layer. The roughness of a layer is defined as the 207
standard deviation of z coordinates of phosphor atoms within each layer. 208
The number of contacts is defined as the count of the usual distance-based step-like 209
variable: 210
CN2 =∑i,j
si,j
si,j = 1 if ri,j ≤ 0
si,j = 0 if ri,j > 0
ri,j = |ri − rj | − d0 .
(1)
with i and j running over different sets of atom pairs, each term of the pair contained in 211
a different portion of the system. When the two sets of atoms identify, respectively, 212
atoms belonging to positively charged groups (Nζ in Lys and Nη in Arg) and negatively 213
charged groups (Cγ in Asp and Cδ in Glu), we address the contact as an intramolecular 214
salt-bridge. The number of such contacts is indicated as SB and the d0 parameter is 215
chosen as 4 A. As for generic inter-residue contacts, we measured the distance between 216
the centers of mass of sidechains in the two involved residues. In this case, d0 is chosen 217
as 6.5 A. When the contact between aminoacids and lipid molecules is addressed, the 218
center of mass of DMPC molecules is used and the d0 distance is 4.5 A. 219
Elastic moduli 220
Elastic moduli of lipid bilayer were calculated by fitting suitable ensemble averages with 221
the following equations [72]: 222
〈|n‖q |2〉 =kBT
Kcq2
〈|n⊥q |2〉 =kBT
KΘ +Ktwq2.
(2)
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where Kc,KΘ,Ktw are bending, tilt, and twist elastic moduli, respectively, kB is 223
Boltzmann constant, T is temperature, and nq is the reciprocal space vector determined 224
as summarized below (see also supplementary information of Ref. 72 and Ref. 73). 225
The xy plane of the membrane is discretized to a square 8×8 grid. The orientation 226
vector of lipid molecule j is n(α)j (x, y, z) with α 1 or 2 for upper and lower layers, 227
respectively. Each vector points from the midpoint between P and C2(glycerol) atoms 228
to the midpoint between the terminal C atoms of the lipid tails. The orientation vectors 229
are projected onto the xy plane and are mapped onto the 8×8 grid, providing n(α)(x, y). 230
Fast Fourier transform is used to obtain n(α)q , where q is the reciprocal space index. 231
From n(α)q we obtain the quantity 232
nq =1
2[n(1)q − n(2)
q ] , (3)
that is decomposed into longitudinal (n‖q) and transverse (n⊥q ) components: 233
n‖q =1
q[q · nq]
n⊥q =1
q[q× nq] · z .
(4)
Finally Eq. 2 is used to average according to the collected sampling of lipid molecules. 234
Results 235
Addition of a divalent cation to the DMPC bilayer 236
The affinity of Mg2+ for the DMPC bilayer was measured by the umbrella sampling 237
method (see Supporting Information, Fig.S1 in ). The free energy minimum was found 238
at 17 A from the bilayer center, thus corresponding to the average distance of P atoms 239
(see below). The flatter shape of free energy around the minimum in the case of Na+ is 240
due to the equivalent interactions of Na with phosphate and carbonyl groups of DMPC. 241
These interactions allow a deeper penetration of Na into the bilayer than Mg. The 242
binding free energy of Mg2+ was estimated as about four times that of Na+. This 243
difference favours the binding of Mg to the DMPC surface compared to Na. This 244
difference is opposite to what expected on the basis of dehydration free energy, that 245
should favour Na compared to Mg, being the hydration free energy at 300 K about five 246
times more negative for Mg compared to Na [74]. This effect is due to the strong 247
electrostatic interactions formed by Mg when absorbed by phosphate groups, together 248
with a significant drift of water molecules towards the bilayer center along with the 249
cation’s penetration. Therefore, interactions with phosphate oxygen and with residual 250
water molecules strongly compensate the loss of water molecules from the Mg 251
first-coordination sphere when Mg is driven from the bulk water towards the bilayer 252
center. 253
All of the 3 CMD trajectories of Mg/DMPC display a rapid approach of the divalent 254
cation (Mg2+) from the bulk to the initially closest layer. After 200 ns, the divalent 255
cation is trapped by phosphate groups of DMPC. Since the 3 CMD trajectories are 256
equivalent in several average properties (like the radial distribution function g, see 257
Methods), the average over the 3 trajectories is analyzed in the following. We indicate 258
the cation-bound layer as layer 1 (L1) and the layer not affected by the binding as layer 259
2 (L2). The difference between g calculated for L1 and L2 is displayed in Fig 1. The 260
divalent cation (black) is bound to the phosphate oxygen atoms, thus displaying the 261
coordination distance of 2.9 A with respect to P atoms. Including the second-shell P 262
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atoms (the peak at 3.5 A), the number of P atoms around the cation is 4. This 263
coordination affects the average distance between charged groups within L1, as it is 264
displayed by the P-P distances (red line), respectively, within each layer L1 and L2. 265
Conversely, atoms farther than P from the perturbing cation are less affected, as shown 266
by the difference in N-P distance distribution among the two layers (blue line). 267
0
200
400
600
800
1000
2 3 4 5 6 7 8 9 10
0
2
4
6
8
10
∆g
L1−
L2
r (Å)
Mg−PP−PN−P
Fig 1. Effect of Mg addition to DMPC. Difference between radial distributionfunction (g) computed in Mg/DMPC for layer 1 (Mg-bound) and layer 2. Mg-P (blackline); P-P (red line); N-P (blue line). Left y-axis is for black line, right y-axis is for redand blue lines.
The formation of a cluster of phosphate groups in L1 induces the release of the 268
electrostatic interactions within the head groups in each layer. Therefore, a consequence 269
of the phosphate neutralization by Mg binding to L1, is a change in the distribution of 270
monovalent counterions at the interface of the two different layers. This effect is 271
emphasized by plotting the difference in K-P radial distribution function between the 272
two layers and by comparing this quantity with the same quantity computed in the 273
absence of divalent cation. In Fig 2A it can be noticed that the distribution of K+ in 274
the presence of Mg (black curves) is more asymmetric than with no Mg (red curves). 275
The low symmetry of K-P distribution in the absence of Mg (red curves) is due to 276
sampling limitations. Indeed, the presence of Mg on the L1 layer displays a “hole” in K 277
distribution where there is a little excess in the absence of Mg. Because of the change in 278
interactions between K+ and P at short distance (the peaks at the left), there is also a 279
decrease of bulk concentration within a distance of 1 nm from the P atoms. This change 280
of the electrostatic properties between the two sides of the bilayer is equivalent to a weak 281
polarization of the membrane. This asymmetry is caused by the asymmetry in the P-P 282
radial distribution (Fig 2B), that is due to the formation of the Mg-O(P) coordination. 283
The asymmetry of the interactions between divalent cations added from one side of 284
the bilayer is consistent with experimental data reported for exogenous addition of Cu2+285
and Zn2+ to bilayer models (POPC/POPS mixtures) [53]. The comparison between 2H 286
and 31P ss-NMR spectra of POPC/POPS molecules shows that P atoms are strongly 287
affected, while the molecular tails in the hydrophobic region of the bilayer are almost 288
unaffected. The addition of Cu2+ to these membranes induces the formation of smaller 289
vesicles, thus showing a dramatic effect of this ion on the bilayer stability. 290
The effect of the divalent cation on the elastic property of DMPC is also significant. 291
In Table 2 we report the elastic constants determined by the different simulations, with 292
averages of Eq. 2 (see Methods) computed over all the acquired trajectories (see 293
Table 1). 294
The values are in the range of those found in DPPC atomistic simulations [72], 295
though the conditions (temperature, force-field, etc.) are different. The bending 296
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(A) (B)
−2−1.5
−1−0.5
0 0.5
1 1.5
2 2.5
3
2 3 4 5 6 7 8 9 10
∆g
r (Å)
K−P Mg/DMPCK−P DMPC
−2−1.5
−1−0.5
0 0.5
1 1.5
2 2.5
3
2 3 4 5 6 7 8 9 10
r (Å)
P−P Mg/DMPCP−P DMPC
Fig 2. Effect of Mg addition to DMPC. Difference between radial distributionfunction (∆g) computed for layer 1 (Mg-bound) and layer 2. (A) K-P in Mg/DMPC(black line, average of trajectories 1-3); K-P in DMPC (red line, trajectories 1-4). (B)P-P in Mg/DMPC (black line, trajectories 1-3); P-P in DMPC (red line, trajectories1-4).
Table 2. Elastic moduli of DMPC bilayer with no addition (DMPC) andinteracting with, respectively, a divalent cation (Mg/DMPC), the Aβpeptide (Aβ/DMPC), and the Cu-Aβ peptide (Cu-Aβ/DMPC). Average iscomputed over 10 windows of 20 ns each, during the last 200 ns of eachCMD trajectory. Standard error is within parenthesis.
Elastic moduli DMPC Mg/DMPC Aβ/DMPC Cu-Aβ/DMPC
Kc (10−20 J) 7.859 (0.369) 14.568 (0.756) 13.316 (1.307) 15.210 (2.077)Kθ (10−20 J/nm2) 6.679 (0.191) 5.200 (0.200) 6.767 (0.241) 7.095 (0.200)Ktw (10−20 J) 1.447 (0.010) 1.629 (0.006) 1.668 (0.061) 1.668 (0.042)
constant (Kc) of pure DMPC is smaller than in all the other cases, where the DMPC is 297
perturbed by exogenous addition of species. This change shows that the addition of any 298
species on one side of the bilayer increases the rigidity of curvature, because of the 299
change exerted more on one layer than on the opposite layer. On top of this effect, that 300
is due to the asymmetry of the addition, the tilt modulus (Kθ) is significantly smaller 301
for Mg/DMPC compared to the DMPC bilayer both unperturbed (DMPC) and with 302
the peptide (Aβ/DMPC and Cu-Aβ/DMPC) floating over the bilayer surface. This 303
additional information reveals that the formation of bridges between phosphate groups 304
occurring in Mg/DMPC (see Fig 1) produces a cluster of 3-4 lipid molecules that 305
changes the elasticity of DMPC. As described above (and also in detail below), the lipid 306
molecules belonging to the cluster are more rigid and create a small hollow in the 307
surface. The perturbation exerted by Mg-phosphate interactions makes a little hollow 308
over the bilayer surface affected by Mg binding. This little hollow can be observed 309
looking at the configurations where the Mg penetration is deep, like in Fig 3. This local 310
perturbation allows the molecules neighbor to the cluster to more easily tilt with respect 311
to the bilayer normal. 312
The effect of Mg addition to L1 does not significantly alter other structural 313
parameters of the bilayer at the same temperature (see Table 3). For instance, bilayer 314
thickness and area per lipid compare well with the values measured by diffraction 315
studies for DMPC [75]. Experiments report thickness at T =303 and 323 K of, 316
respectively, 36.7 and 35.2 A2, while in our MD simulation at 311 K thickness is 317
34.4 A2. This small difference may be due to the slightly different way used to measure 318
the thickness (see Methods and Ref. 75). The experimental area per lipid is 59.9 and 319
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(A) (B)
Fig 3. Effect of Mg addition to DMPC. Configuration of Mg/DMPC where thedistance between Mg (purple sphere) and the bilayer central plane is minimal alongwith the CMD simulations 1-3. P atoms in DMPC are represented as yellow spheres,those within 3.5 A from Mg are emphasized in orange. The other DMPC molecules arerepresented as thin bonds. Water and KCl are not displayed. Atomic radii are arbitrary.Panel B is the same structure in A observed from the z axis and with only lipidmolecules in L1 displayed.
63.3 A2 at the same two probed temperatures, while it is 63.8 at 311 K. Negligible 320
effects are observed for the average roughness with the Mg2+ addition (see Table 3), 321
thus confirming that any effect do to Mg/DMPC association is very localized in space. 322
Table 3. Bilayer structural data averaged over the second half of all trajectories (avg.) and selectedtrajectories (traj./REMD). Root-mean square errors are within brackets.
Simulation Area per lipid (A2) Thickness (A) Roughness L1 (A) Roughness L2 (A)
DMPC 63.75(0.05) 34.4(0.2) 2.4(0.3) 2.5(0.4)Mg/DMPC 63.75(0.05) 34.3(0.2) 2.5(0.4) 2.5(0.4)Aβ/DMPC (REMD) 64.5(0.1) 34.4(0.2) 2.5(0.3) 2.5(0.3)Cu-Aβ/DMPC (REMD) 64.4(0.1) 34.4(0.2) 2.5(0.3) 2.5(0.4)Aβ/DMPC (avg.) 60.6(1.4) 35.6(0.6) 2.7(0.5) 2.7(0.5)Cu-Aβ/DMPC (avg.) 60.6(1.2) 35.6(0.6) 2.7(0.5) 2.7(0.5)Aβ/DMPC (traj. 1) 61.6(1.1) 35.5(0.5) 2.6(0.4) 2.6(0.4)Aβ/DMPC (traj. 5) 60.8(1.6) 35.4(0.7) 2.7(0.4) 2.7(0.5)Cu-Aβ/DMPC (traj. 8) 60.9(1.1) 35.6(0.5) 3.2(0.9) 3.3(0.9)
Exogenous addition of Aβ peptide to the bilayer 323
In the REMD Aβ/DMPC and Cu-Aβ/DMPC simulations the DMPC bilayer is in the 324
liquid crystal phase at all the probed temperatures, consistently with similar MD 325
simulations reported in the literature [76]. The temperature dependence of the area per 326
lipid in Aβ/DMPC REMD simulation is displayed in Fig 4, together with the available 327
experimental results for DMPC [75], the result for CMD at T =311 K for DMPC, and 328
the average of 10 CMD trajectories at T = 303 K described below. The behavior for 329
Cu-Aβ/DMPC is not graphically distinct from Aβ/DMPC and, therefore, it is not 330
displayed. The REMD simulation is able to capture the increase of area per lipid (A) as 331
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T increases as well as the area per lipid at high T , but it is dominated by high-T lipid 332
configurations that are often exchanged in REMD with low-T configurations. However, 333
REMD can adequately probe the possibility of peptide penetration at the highest area 334
per lipid accessible, both by experiments and simulations, in the liquid crystal phase of 335
DMPC. Therefore, it is expected that for lower A peptide penetration would be more 336
difficult than at high T . 337
58
59
60
61
62
63
64
65
66
67
300 305 310 315 320 325 330 335
A (
Å2 )
T (K)
REMDExp.MD
Fig 4. Area per lipid: comparison with experiments. Area per lipid (A) as afunction of temperature (T ): average results for REMD simulation (black squares);experimental results at 303, 323, and 333 K (red squares [75]); average of 10 CMDsimulations for Aβ/DMPC at 303 K and DMPC at 311 K (blue squares).
In Fig 5 we display the radial distribution function g for selected pairs, to show the 338
extent of penetration of N- and C-termini (respectively Nt and Ct) through the 339
membrane surface (using P atoms in the pair) or towards the membrane center (using 340
the terminal C atom in the two acyl chains of DMPC, Cf hereafter). The g function is 341
measured at T =311 K, i.e. the physiological temperature of the synaptic membrane. 342
The REMD trajectory at 311 K shows that the propensity for Aβ and Cu-Aβ N-termini 343
to interact with the membrane surface is limited to the head groups of the DMPC 344
bilayer, the P atoms. The peaks in Fig 5A (black lines for Aβ/DMPC) represent the 345
electrostatic interaction between the positively charged Nt group of Aβ with the 346
negatively charged phosphate groups (see also the number of salt-bridges discussed 347
below). The peptide N-terminus (residues 1-16) contains most of the charged sidechains 348
and it is the peptide segment involved in metal ion binding. For this reason the 349
behavior of N- and C-termini are expected to be different when they are in contact with 350
a charged membrane. The approximate symmetry of the g function measured for 351
different layers in the bilayer membrane (L1 and L2) shows that in both conditions the 352
N-terminus of the peptide is floating above the membrane surface, going back and forth 353
from one layer to the other. The lower symmetry of Aβ/DMPC (black lines) compared 354
to Cu-Aβ/DMPC (red lines) shows that even the wide REMD sampling is not fully 355
adequate to capture the intrinsic symmetry of the system when electrostatic interactions 356
occur. 357
The Aβ peptide Nt atom approaches the P atoms at 3.5 A, while Cu in Cu-Aβ 358
rarely reaches a distance lower than 6.5 A. The Cu-binding to Aβ reduces the 359
interactions between the N-terminal region of the Aβ peptide and DMPC head groups, 360
producing a more symmetric g function among the two layers. This effect is expected 361
since the interaction with Cu spreads the positive charge over the Cu-bound residues, 362
while in the charged N-terminus (when not bound to Cu) of the Aβ peptide, the 363
positive charge density is higher and the interactions with negatively charged groups at 364
the bilayer interface are more likely. 365
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(A) (B)
0
0.2
0.4
0.6
0.8
1
2 4 6 8 10 12 14 16 18 20
g
r (Å)
Nt−P(L1)Nt−P(L2)Cu−P(L1)Cu−P(L2)
0
0.2
0.4
0.6
0.8
1
2 4 6 8 10 12 14 16 18 20
g
r (Å)
Ct−P(L1)Ct−P(L2)Ct−P(L1)Ct−P(L2)
0
0.02
0.04
0.06
0.08
0.1
0.12
2 4 6 8 10 12 14 16 18 20
g
r (Å)
Nt−Cf(L1)Nt−Cf(L2)Cu−Cf(L1)Cu−Cf(L2)
0
0.02
0.04
0.06
0.08
0.1
0.12
2 4 6 8 10 12 14 16 18 20
g
r (Å)
Ct−Cf(L1)Ct−Cf(L2)Ct−Cf(L1)Ct−Cf(L2)
(C) (D)
Fig 5. Radial distribution functions by REMD. Radial distribution function (g)computed for layer 1 (thick line) and layer 2 (thin line) in REMD simulations forconfigurations at T =311 K. Notice that y range in bottom panels is 1/10 of that in toppanels. (A) Nt-P in Aβ/DMPC (black lines) and Cu-P in Cu-Aβ/DMPC (red lines);(B) Ct-P in Aβ/DMPC (black lines) and Ct-P in Cu-Aβ/DMPC (red lines); (C) Nt-Cfin Aβ/DMPC (black lines) and Cu-Cf in Cu-Aβ/DMPC (red lines); (D) Ct-Cf inAβ/DMPC (black lines) and Ct-Cf in Cu-Aβ/DMPC (red lines).
The peptide rarely penetrates the membrane bilayer, as shown by the g function for 366
pairs involving the Cf atoms (the bottom of the acyl chains in lipid molecules, 367
Figs 5C-D). According to bilayer structure (see results reported below) the average 368
distance between P atoms and the center of the bilayer is about 17 A. Therefore, the Nt 369
atom for Aβ/DMPC (black lines in panel C) and the Ct atom in Cu-Aβ/DMPC (red 370
lines in panel D) significantly approach the bilayer center, showing a deep penetration 371
in rare configurations in the trajectory. Noticeably, when Cu is bound to the peptide 372
(red lines) penetration occurs from the C-terminus, while when Cu is absent the 373
N-terminus is allowed to move from the surface (P atoms) towards the bilayer center. 374
The representation of this change in penetration is better understood examining the few 375
snapshots contributing to the contribution to g at short distances in, respectively, Cf-Nt 376
(Aβ/DMPC, Fig 5C) and Cf-Ct (Cu-Aβ/DMPC, Fig 5D). In Fig 6 we display, left and 377
right panels, one of such configurations for, respectively, each of the two systems. It can 378
be observed that a common feature of the peptide structure in these configurations is 379
the breaking of cross-talk between the N- and C-termini. This cross-talk is always 380
present when the peptide (both Aβ and Cu-Aβ) are in water solution and it is often 381
maintained when the peptide interacts with the membrane surface. The interplay 382
between the release of intra-peptide interactions and penetration into the bilayer is 383
discussed in more detail below. 384
The number of intramolecular salt-bridges (SB) within the peptide (Table 4) is 385
consistent with the data reported for the simulation of the same peptides in water (last 386
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(A) (B)
Fig 6. Penetration into DMPC. Configurations of Aβ/DMPC (left) andCu-Aβ/DMPC (right) displaying the deepest penetration into the lipid bilayer inREMD simulations. The configurations are those where the distance between anypeptide atom and any of the bilayer Cf atoms (the terminal methyl group of acylDMPC sidechains) is minimal along with the trajectory at T =311 K. The peptide isrepresented as bonds (N-terminal residues 1-16 in black, C-terminal residues 17-42 inred), Cu as a purple sphere. P atoms in DMPC are represented as yellow spheres. Theother DMPC molecules are represented as thin bonds. Water and KCl are not displayed.Atomic and bond radii are arbitrary.
columns). For Aβ/DMPC SB is similar to the value in water, with N(Asp 1) providing 387
a contribution of approximately 1 in both cases. This shows that despite the few 388
interactions between the N terminus and the phosphate groups of DMPC, the 389
intramolecular salt-bridge involving N(Asp 1) in the peptide is not statistically broken 390
and the monomeric peptide keeps the network of intramolecular salt-bridges almost 391
intact. This result is consistent with the rare events of membrane penetration observed 392
in REMD at T =311 K. Also in Cu-Aβ/DMPC SB does not change with respect to the 393
value in water. These data show that the N-terminus of Aβ(1-42) and Cu-Aβ(1-42) is 394
bent towards the peptide by, respectively, intramolecular salt-bridges and covalent 395
bonds involving Cu. Thus, N-terminus is rarely released by the peptide cross-talk to 396
form new interactions with the DMPC phosphate groups. 397
Table 4. Structural data averaged over the second half of all trajectories(avg.) and selected trajectories (traj./REMD). See Methods for definitions.Root-mean square errors are withing brackets.
Simulation SASA (nm2) SB β (%) helix (%) Rg (nm)
Aβ/DMPC (avg.) 33(3) 2.7(1.1) 7.9 11.1 1.1Cu-Aβ/DMPC (avg.) 35(2) 2.9(1.1) 6.2 11.2 1.1Aβ/DMPC (REMD) 35(3) 2.5(1.2) 9 12 1.1Cu-Aβ/DMPC (REMD) 38(3) 2.2(1.0) 8 7 1.3Aβ/DMPC (traj. 1) 39(2) 3.0(0.9) 0.0 15.1 1.3Aβ/DMPC (traj. 5) 30(1) 3.1(0.8) 2.8 1.9 1.0Cu-Aβ/DMPC (traj. 8) 33(2) 3.2(0.6) 0.1 20.0 1.0Aβ 32(2) 2.8(1.0) 10.0 4.2 1.0Cu-Aβ 36(2) 2.8(1.3) 0.6 1.2 1.1
The bilayer structure (Table 3) shows only a moderate propensity for larger thermal 398
fluctuations, induced by the perturbation due to weak interactions with the peptide, 399
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and a small increase in thickness. 400
Because of the extended conformational sampling in REMD, in both cases the 401
peptide N-terminus moves back and forth between the two layers, because of the usual 402
periodic boundary conditions used in simulations. As a consequence of the weak 403
interactions between the peptide and the DMPC bilayer, the distributions of K-P and 404
P-P distances are approximately symmetric among the two layers and almost identical 405
to those of pure DMPC (data not shown here). The peptide does not change the 406
distribution of monovalent ions. 407
In order to extract more information about possible specific interactions favoring 408
asymmetry in structural and electrostatic properties among the two layers, in the 409
following we compare 10 separated long (1 µs) CMD simulations performed for both 410
Aβ/DMPC and Cu-Aβ/DMPC models. 411
Comparing different peptide/DMPC associations 412
In this section, the NPT-ensemble MD simulations (that we indicate as conventional 413
MD, CMD) of Aβ/DMPC and Cu-Aβ/DMPC are described. Since the sampling in 414
CMD is more limited than in REMD, the different trajectories allow a comparison 415
between different kinds of Aβ/DMPC and Cu-Aβ/DMPC association. 416
In Fig 7, in order to describe the type of association, the distance along the z axis 417
between the bilayer center and the closest atom of the peptide is displayed as a function 418
of time for all trajectories. Among 10 1 µs-long trajectories acquired for each of the two 419
species, Aβ/DMPC (panel A) and Cu-Aβ/DMPC (panel B), respectively, we observe 420
the rapid incorporation of the peptide into the bilayer in one trajectory only, trajectory 421
1 of Aβ/DMPC. As for Aβ/DMPC, we observe a partial incorporation after 600 ns for 422
trajectory 5, while for Cu-Aβ/DMPC a moderate bilayer penetration is observed for 423
trajectory 8. These data show that in most of the cases the peptide interacts with head 424
groups (around P atoms). On average, the distance between Cu and the center of the 425
membrane is 42.0±10.6 A for Cu-Aβ/DMPC compared to 15.3±2.4 A for Mg in 426
Mg/DMPC. In all simulations the bilayer thickness is about 34 A (see Table 3 and 427
discussion below), thus the average distance between P atoms and the central plane of 428
the bilayers is never below 17 A. The approach of Mg towards the bilayer central plane 429
does not significantly drift, on average, the P atoms towards the center of the bilayer, 430
because the density of P atoms projected along the z axis does not change (data not 431
shown here). However, as described above, the perturbation makes a little hollow over 432
the bilayer surface affected by Mg binding (see Fig 3 and discussion above). 433
(A) (B)
−10−5 0 5
10 15 20 25 30 35 40 45 50 55 60 65 70 75 80
0 100 200 300 400 500 600 700 800 900 1000
Pene
trat
ion
(Å)
Time (ns)
traj 1traj 2traj 3traj 4traj 5traj 6traj 7traj 8traj 9
traj 10
−10−5 0 5
10 15 20 25 30 35 40 45 50 55 60 65 70 75 80
0 100 200 300 400 500 600 700 800 900 1000
Pene
trat
ion
(Å)
Time (ns)
traj 1traj 2traj 3traj 4traj 5traj 6traj 7traj 8traj 9
traj 10
Fig 7. Penetration into DMPC. Penetration of Aβ(1-42) (left, Aβ/DMPC) andCu-Aβ(1-42) (right, Cu-Aβ/DMPC) into the lipid bilayer. y axis is the z coordinate ofthe lowest atom (minimal z) of peptide. The horizontal line at y=0 indicates the centerof geometry of the bilayer which is the average of z coordinates of all DMPC’s atoms.The horizontal line at 17.7 A shows the average position of all P atoms.
These observations are consistent with the experimental data reported for exogenous 434
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addition of Aβ(1-42) to bilayer models (POPC/POPS mixtures) [53]. Comparing 2H 435
and 31P solid state-NMR of Aβ(1-42) and Cu-Aβ(1-42), a neat indication of the 436
confinement of peptides around the head groups is shown. Peptide incorporation during 437
the bilayer preparation, on the other hand, has more severe impact on NMR data and 438
bilayer stability, irrespective of Cu addition. 439
Effect of peptide addition to DMPC bilayer structure 440
The area per lipid as a function of temperature measured by REMD simulation (see 441
above) and consistent with experimental data [75] shows that the area per lipid 442
increases with temperature. Therefore, most of the changes displayed in Table 3 are due 443
to the lower T used in the CMD simulations of Aβ/DMPC and Cu-Aβ/DMPC (T =303 444
K) compared to DMPC and Mg/DMPC (T =311 K). The choice of T =303 K is to 445
compare these results to CMD simulations of Aβ(1-42) and Cu-Aβ(1-42) in the absence 446
of DMPC [52]. Despite the more significant effect of peptide/DMPC interactions in the 447
10 separated CMD than in REMD, the changes in bilayer structural parameters 448
(Table 3) are consistent with the experimental data [53] that show a small structural 449
effect for the bilayer, when addition of both Aβ(1-42) and Cu-Aβ(1-42) to the 450
POPC/POPS bilayer is exogenous. On the other hand, the peptide incorporation has a 451
more significant effect on the structure of DMPC head groups, as it discussed in the 452
next subsections. As for bilayer thickness, in our simulations we observe a few 453
incorporated samples, but in all cases where peptide incorporation occurs the thickness 454
of the bilayer is not dramatically affected, compared to the case where the peptide is 455
confined at the membrane surface. The change in area per lipid is, on the other hand, 456
more significant for trajectory 1 (61.6 A2) compared to the average (60.6). This shows 457
that peptide digs a little hollow separating the lipid molecules one from each other, with 458
no wide changes in the bilayer structure, like those emerging from the displacement of a 459
lipid head group from the layer to the solvent. 460
The order parameters of hydrophobic DMPC chains (data not shown here) show a 461
negligible effect of both Aβ and Cu-Aβ exogenous addition to DMPC. This is an 462
expected effect, since the penetration of the peptide into the bilayer is small (see 463
Fig 7B). 464
Effect of peptide addition to DMPC on electrostatic properties 465
We extend the measure of the effects of interactions between peptide and the DMPC 466
head groups on the distribution of monovalent ions (K+) on the two layers. Again, to 467
better understand these effects we analyze the different CMD trajectories. In Fig 8, we 468
compare the radial distribution function for pairs involving P atoms in DMPC and 469
atoms in the N-terminus of the peptide, N(Asp 1) and Cu in, respectively, Aβ/DMPC 470
and Cu-Aβ/DMPC. For instance, comparing trajectories 1 and 2 for Aβ/DMPC and 471
Cu-Aβ/DMPC, we notice that the more symmetric is the interaction between the 472
peptide among the two layers (left panels), the more symmetric is the distribution of K+473
(right panels). It is also interesting to notice that the strong interaction of trajectory 1 474
for Aβ/DMPC (see above), produces a polarization of K+ that is opposite to that 475
produced by Mg2+ (Fig 2A, black curve). 476
Effect of Cu and DMPC on peptide structure 477
Circular dichroism provides important experimental information about the change of 478
structure of Aβ(1-42) and Cu-Aβ(1-42) when the peptides are added to the preformed 479
bilayer [53]. When these experiments are performed at low peptide concentration (by 480
using synchrotron radiation sources), aggregation phenomena are minimized during the 481
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0
0.005
0.01
0.015
0.02
0.025
0.03
0.035
2 4 6 8 10 12 14 16 18 20
g
r (Å)
Traj. 1
Nt−P(L1)Nt−P(L2)Cu−P(L1)Cu−P(L2)
−0.003
−0.002
−0.001
0
0.001
0.002
0.003
2 4 6 8 10 12 14 16 18 20
∆g
r (Å)
Traj. 1
0
0.005
0.01
0.015
0.02
0.025
0.03
0.035
2 4 6 8 10 12 14 16 18 20
g
r (Å)
Traj. 2
Nt−P(L1)Nt−P(L2)Cu−P(L1)Cu−P(L2)
−0.003
−0.002
−0.001
0
0.001
0.002
0.003
2 4 6 8 10 12 14 16 18 20
∆g
r (Å)
Traj. 2
Fig 8. Radial distribution function. Radial distribution function (g, left panels)and radial distribution difference (∆g, right panels) computed for layer 1 (thick line)and layer 2 (thin line). Nt-P in Aβ/DMPC (black line, left); Cu-P in Cu-Aβ/DMPC(red line, left); K-P in Aβ/DMPC (black line, right); K-P in Cu-Aβ/DMPC (red line,right); Trajectory 1 (top); trajectory 2 (bottom).
measurements. These experiments show that the change of structure of the peptide is 482
minimal, both without and with Cu, when peptides are added to the bilayer. A more 483
significant change occurs when peptides are incorporated during bilayer formation and, 484
in the latter case, the addition of Cu is also affecting the structural modification. In 485
Fig 9 we report the average secondary structure of the peptide, both without DMPC 486
(top, data from Ref. 52) and with DMPC (bottom, this work). The data show that the 487
effect of DMPC association on the peptide is on average small: there is only a 488
significant increase in population of helical regions together with a spreading of the 489
β-sheet content among residues. We notice that simulations with no membrane have 490
been performed with a different force-field (AMBER FF99SB). 491
In Table 4 we compare structural parameters averaged over 10 trajectories, with 492
those obtained for some selected trajectories, the latter showing the largest extent of 493
association with DMPC. As for those trajectories that are more strongly interacting 494
with the bilayer (especially trajectories 1 of Aβ/DMPC and 8 of Cu-Aβ/DMPC) the 495
helical content is significantly increased. This is an expected result, since it is well 496
known that the incorporation of Aβ(1-40) into vesicles produces α-helical motifs in the 497
peptide [77]. It must be noticed that when the peptide is embedded into the bilayer 498
(Aβ/DMPC, traj. 1) there is an expansion of the peptide, while the association with the 499
bilayer surface (Aβ/DMPC, traj. 5, Cu-Aβ/DMPC, traj. 8) induces a significant 500
compaction. The size and secondary structure of the peptide is, therefore, significantly 501
modulated by the type of association when the latter occurs: electrostatic (strong 502
interaction with bilayer surface) versus hydrophobic (penetration into the bilayer). 503
The penetration of the peptide into the membrane increases, as expected, the helix 504
content. The maximal percentage of helix is displayed by the trajectories where the 505
penetration is deeper: trajectory 1 for Aβ/DMPC and trajectory 8 for Cu-Aβ/DMPC, 506
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(A) (B)
0
20
40
60
80
100
1 2 3 4 5 6 7 8 910
11
12
13
14
15
16
17
18
19
20
21
22
23
24
25
26
27
28
29
30
31
32
33
34
35
36
37
38
39
40
41
42
Sec
on
dar
y s
tr.
(%)
Residue index
sheet(10%)turn(19%)
coil(66%)helix(4%)
0
20
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(C) (D)
Fig 9. Secondary structure. Secondary structure (see Methods for definition) as afunction of residue in Aβ. Top: (A) Aβ(1-42) and Cu-Aβ(1-42) (B) without DMPC [52].Bottom: secondary structure averaged over 10 trajectories, Aβ(1-42)/DMPC (C) andCu-Aβ(1-42)/DMPC (D).
15% and 20%, respectively (Table 4). These percentage is lower than that reported for 507
Aβ(1-42) in micelles on the basis of CD and NMR experiments in SDS [78] and in 508
helix-inducing solvents [79]. The difference is due to the partial achievement of peptide 509
penetration in our simulation because of the exogenous addition. On the other hand, 510
experiments in micelles and in apolar solvents are performed by peptide incoroporation 511
into the microenvironment. 512
The number of intramolecular salt-bridges is, on average over the 10 trajectories, not 513
altered in the presence of DMPC with respect to the case of water solution (Table 4). 514
The SB quantity increases when the association of the peptide with DMPC is more 515
significant (trajectories 1 and 5 for Aβ/DMPC, trajectory 8 for Cu-Aβ/DMPC). The 516
number of contacts between positively charged groups in Aβ (see Methods) and P 517
atoms, does not increase substantially, being always around 0.2, independently from the 518
chosen trajectory (data not shown in Tables). The number of contacts between 519
negatively charged groups in the peptide and the ammonium group in DMPC is always 520
negligible, because of the steric effect of methyl groups attached to the N atom. These 521
data indicate that the extent of association between peptide and membrane is 522
independent from the electrostatic interactions between charged groups in the peptide 523
and those with opposite charge at the membrane surface. Charged head groups in the 524
membrane are on average not sufficient to divert charged groups in the peptide from 525
pre-existent salt-bridges. 526
A further illustration of the type of interactions occurring in the peptide/DMPC 527
association can be obtained by examining and comparing the final configurations of 528
trajectories characterized by a different behavior. We limit this comparison, reported in 529
Fig 10, to Aβ/DMPC, since the difference with Cu-Aβ/DMPC is, in this respect, 530
marginal. The final configuration in trajectory 2 (top) represents a typical weak 531
interaction between an almost unperturbed Aβ peptide and the surface of DMPC. 532
Trajectory 5 (middle) ends with configurations significantly penetrating the membrane 533
bilayer, but with interactions almost confined to the surface. Finally, in trajectory 1 the 534
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peptide rapidly achieves the penetration of the bilayer from the side of its C-terminus 535
(bottom). In the latter conditions, it can be noticed that the region of Aβ crossing the 536
layer surface is small, separating the N-terminus (above the surface) and the C-terminus 537
(below the surface). This configuration, again, represents the requirement of removing 538
the cross-talk between the N-terminus and the C-terminus (exerted by the bending of 539
N-terminus towards the C-terminus) before a deeper penetration of the peptide into the 540
membrane from the side of the C-terminus. This configuration is similar to that 541
obtained by REMD of Cu-Aβ/DMPC displaying the deepest penetration into the 542
bilayer (Fig 6B), with the main difference that the N-terminus is not partially 543
neutralized by Cu binding. 544
The further comparison between statistical properties in the three different 545
simulations represented by the snapshots described above, confirms the description of 546
the force that is exerted by the DMPC bilayer when the peptide is incorporated. In the 547
left panels of Fig 11 the probability of inter-residue contacts (see Methods) is displayed 548
for trajectories 2 (top), 5 (middle), and 1 (bottom panels). In the first case there are 549
almost no interactions between Aβ(1-42) and DMPC, since the number of Aβ-DMPC 550
contacts is 5. In trajectory 5 significant interactions of Aβ(1-42) with the bilayer 551
surface are revealed by an increase in the number of Aβ-DMPC contacts to 13. Finally, 552
in trajectory 1 the deepest penetration of the peptide into the bilayer occurs and the 553
number of contacts increases to 49. Again, trajectory 2 (top panel) displays a typical 554
behavior for an unperturbed Aβ(1-42) peptide, where a weak cross-talk between many 555
residues is allowed by the structural disorder of the peptide. As already observed for the 556
monomeric Aβ(1-42) peptide in water solution, contacts are distributed among two 557
domains, one N-terminal and one C-terminal, as it is shown by the low probability of 558
contacts in the range of residues 20-26. In the case of interactions confined to the 559
DMPC bilayer surface (trajectory 5, middle panel), we observe a conformational 560
freezing, displayed by an increase, with respect to the free peptide, of highly populated 561
contacts between residues far in the sequence. Some of them involve Glu 22, Asp 23, 562
and Lys 28, with these charged sidechains interacting mostly with the N-terminus and 563
not between themselves. In the case of a peptide that is more significantly embedded 564
into the bilayer (trajectory 1, bottom panel), one notices the disappearing of contacts 565
within residues in the C-terminus and the extension of the N-terminal domain up to Lys 566
28, with the void observed for trajectory 2 (top) almost filled. This change in cross-talk 567
is induced by the formation of contacts between the C-terminus and DMPC. In the 568
right panels of the same figure, we display the mass density for different atomic sets in 569
Aβ(1-42). S1 is the N-terminus, S4 the C-terminus, while S2 is the hydrophobic segment 570
and S3 contains the charged residues involved in one of the intramolecular SBs. When 571
the peptide is out from the bilayer (trajectory 2, top-right panel) only the N-terminus 572
(S1) is approaching the bilayer surface. The analysis of the trajectories not displaying 573
penetration into the bilayer (all trajectories except 1 and 5, data not shown here) shows 574
that there is no preference among the different segments for weak interactions with the 575
bilayer surface. When a more significant interaction with the bilayer surface occurs 576
(trajectory 5, middle-right panel) the hydrophobic segment S2 is projected towards the 577
bilayer because of the stronger interactions among S3 and S1 (as shown in the 578
middle-left panel). When the penetration is deeper (trajectory 1, bottom-right panel), 579
the S4 segment overtakes the layer of P atoms, with the latter interacting with S3. 580
Interestingly, in these conditions the S2 segment is projected towards the water layer, 581
thus allowing interactions with other monomers in the nearby, especially if 582
pre-organized as in trajectory 5 (middle panel). 583
As for Cu-Aβ/DMPC, 9 of 10 trajectories of display the behavior of Aβ/DMPC in 584
trajectory 2, while only trajectory 8 displays a pattern similar to trajectory 5 in 585
Aβ/DMPC. 586
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Fig 10. On the mechanism of penetration into DMPC. Final configurations ofAβ/DMPC in trajectories 2 (top), 5 (middle), and 1 (bottom). Residues 1-16 are inblack (segment S1 in Fig 11), 17-21 in gray (S2), 22-28 in red (S3), and 29-42 in (S4).The peptide is represented as bond sticks. P atoms in DMPC are represented as yellowspheres. The other DMPC atoms are represented as lines. Water molecules and ions arenot displayed. Bond and atomic radii are arbitrary.
The observations related to contacts, both defined as specific salt-bridges and 587
generic inter-residue contacts, represent the process of changing the cross-talk between 588
domains that are polymorphic in the free Aβ(1-42) peptide. The interactions with the 589
charges on the surface of the membrane bilayer selects configurations that have a low 590
population in the DMPC-unbound state, thus indicating a free energy barrier in the 591
process of peptide penetration through the bilayer surface. The observation that 592
peptide embedding into the membrane is a rare event (1 trajectory over 10) shows that 593
the structural changes accompanying the penetration are hindered by the polymorphism 594
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5 10 15 20 25 30 35 40
5
10
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40
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idue
index
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tag
e o
f ti
me
in c
on
tact
0
0.02
0.04
0.06
0.08
0.1
−50 −40 −30 −20 −10 0 10 20 30 40 50
ρ(z
) (a
.u.)
z (Å)
S1S2S3S4
PKCl
5 10 15 20 25 30 35 40
5
10
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40
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idue
index
0
20
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cen
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0
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−50 −40 −30 −20 −10 0 10 20 30 40 50
ρ(z
) (a
.u.)
z (Å)
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PKCl
5 10 15 20 25 30 35 40
Residue index
5
10
15
20
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35
40
Res
idue
index
0
20
40
60
80
100P
erce
nta
ge
of
tim
e in
co
nta
ct
0
0.02
0.04
0.06
0.08
0.1
−50 −40 −30 −20 −10 0 10 20 30 40 50
ρ(z
) (a
.u.)
z (Å)
S1S2S3S4
PKCl
Fig 11. On the mechanism of penetration into DMPC. Probability, forAβ/DMPC, of inter-residue contacts (left panels, see Methods for details) and density ofmass for different atomic sets as a function of the coordinate z along the bilayer normal(right panels): trajectory 2 (top); trajectory 5 (middle); trajectory 1 (bottom). S1 areresidues 1-16, S2 17-21, S3 22-28, S4 29-42. The density of each component is dividedby the number of atoms in each atomic set.
that characterizes the monomeric Aβ(1-42) peptide. The Cu binding to Aβ(1-40) 595
enhances the spread of configurations over polymorphic states in the monomeric 596
state [61], thus providing a possible entropic explanation to the question why Cu 597
binding reduces the penetration of monomers through the charged DMPC surface. 598
Again, we remind that this analysis is limited to peptide monomers. 599
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Discussion 600
In previous works we analyzed in detail the effect of Cu-binding on the properties of 601
Aβ(1-42) peptide, both in monomeric and dimeric states. One major result of our 602
models for monomers in water is that the interactions between the peptide charged 603
sidechains and the water solvent are enhanced by Cu-binding. This observation is 604
consistent with the longer life-time of Cu-Aβ(1-42) monomers compared to Aβ(1-42), 605
when the Cu:Aβ ratio is 1:1, i.e. when all peptides are bound to Cu [80]. 606
Therefore, by adding Aβ(1-42) and Cu-Aβ(1-42) monomers to DMPC, i.e. a lipid 607
bilayer with charged head groups, the difference in organization of charged sidechains is 608
potentially important. 609
Our models of monomeric Aβ(1-42) and Cu-Aβ(1-42) in contact with the DMPC 610
bilayer confirm the experimental information that the exogenous addition to DMPC of 611
these peptides reveals peptide-membrane interactions that are confined to the charged 612
head groups of the bilayer. The interactions between the peptide and the membrane are 613
concentrated in the head groups also in the few exceptions where the peptides are 614
significantly embedded into the membrane bilayer. The exogenous addition of the 615
peptide to the membrane bilayer does not alter significantly the bilayer structure when 616
free divalent cations are either absent or bound to the peptide. As for the Aβ(1-42) 617
peptide, this fact has been already observed experimentally by means of spectroscopy 618
and diffraction studies [81]. Consistently, dramatic changes of peptide/membrane 619
interactions are observed at conditions where the peptide is truncated to be more 620
hydrophobic (Aβ(25-35)) or forms fibril assemblies [81,82]. 621
The picture of Aβ monomers floating over the membrane surface is consistent with 622
other observations reported in the literature. A recent FRET experimental work [4] 623
describes the strong interactions among growing fibrils and the DOPC membrane, 624
modelled as a lipid vesicle. The same study confirms that monomers do not directly 625
bind the lipid bilayer, as already observed in previous studies. 626
As for the impact on oligomer formation, our results point out the possible role of 627
charged groups of the bilayer in organizing monomers into oligomers. Indeed, several 628
simulations showed that a strong association between Aβ and zwitterionic and charged 629
membranes occurs starting from tetrameric Aβ assemblies [15]. Since it is known that 630
the lag-time of monomers associated to Cu is larger than that of Cu-free Aβ when in 631
the water solvent [80], it is not surprising that the DMPC association with Aβ(1-42) in 632
the absence of divalent cations does not decrease the chance of inter-monomer contacts 633
compared to the water solution. The bilayer-water interface, when bilayer has charged 634
groups on the surface, exerts a mild attraction for Aβ(1-42) thus decreasing the freedom 635
of monomers by reducing the space dimensionality. Conversely, at oligomeric level the 636
bilayer surface can assist the formation of larger oligomers and protofibrils. This type of 637
association has been observed in models of preformed protofibrils interacting with lipid 638
bilayers [14]. 639
We notice here that in ss-NMR experiments, the effect of the addition of free Cu2+640
and Zn2+ ions on the membrane properties is more dramatic than in the presence of Aβ 641
peptide [53]. Similar strong effects have been observed both experimentally and 642
computationally for free Ca2+ ions [41–43], and Mg and Cu divalent cations are even 643
smaller than Ca2+ in size. For the first time, we show in this study that the Aβ-bound 644
Cu2+ ion does not exert the strong perturbation on the membrane exerted by a free 645
divalent ion. Indeed, the effect of Cu-Aβ monomer on the membrane is weaker than 646
that of the more charged Aβ peptide. 647
Therefore, the formation of the Cu-Aβ complex before an eventual incorporation into 648
the membrane and before an increase in peptide concentration, appears as a protection 649
against membrane destabilization and oxidation. This hypothesis is confirmed by the 650
NMR experiments performed with the Aβ(25-35) peptide, both without and with 651
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Cu [54,81]. Since the N-truncated peptide does not bind Cu, the addition of Cu to the 652
system has an effect on the bilayer that is similar to that of free Cu. 653
Conclusion 654
We perturbed an atomistic model of the DMPC bilayer, representing a very crude 655
approximation of a portion of the cellular membrane facing the synaptic region between 656
neurons, with a single divalent cation (Mg2+) and with Cu-free and Cu-loaded 657
amyloid-β peptides of 42 aminoacid residues in the monomeric form. 658
All the data reported in our simulations represent important structural and 659
electrostatic changes of the bilayer when a single divalent cation interacts with the 660
phosphate groups of DMPC. On the other hand, the presence of the peptide represents 661
a floating molecule, mildly interacting with the bilayer surface, and well suited to 662
sequester divalent cations, in this case Cu2+. The model clearly depicts the possible 663
protective role of the amyloid-β(1-42) peptide in avoiding interactions between Cu2+664
and the synaptic membrane. 665
The model has many limitations. Beyond the limitations in size and number of 666
components, that are common to application of atomistic models, there is the lack of 667
working approximations to interactions between a ion like Cu2+, with available 3d 668
orbitals, and molecules providing a pletora of possible ligand atoms, like phosphate, 669
carboxylate, imidazole, and carbonyl groups, not to mention deprotonated amide 670
backbone nitrogen that are known to bind Cu2+ at physiological pH. These limitations 671
will be removed by polarizable and reactive force-fields, not yet available. 672
The investigation of the events occurring when the concentration of the peptide 673
increases are the future perspective of this study. However, the type of weak 674
interactions of the peptide with DMPC, shows that modulation of inter-peptide 675
electrostatic interactions are likely changing the picture describing the behavior of 676
monomers, where intramolecular salt-bridges are found particularly stable. The 677
assembly of several monomers into oligomers, especially when loaded with Cu2+, is 678
likely affecting the surface of the bilayer. Then, as expected, the increase in 679
concentration of Cu-Aβ(1-42) in the synaptic region becomes the crucial event 680
destabilizing the neuron membrane. The increase in turnover of Cu-Aβ monomers or 681
dimers, possibly because of self-oxidation (the latter enhanced in dimers), can also 682
contribute to membrane protection. 683
Supporting information 684
S1 File. US. Description of umbrella sampling estimate of binding free energy to 685
DMPC for Mg2+ and Na+. 686
S2 File. DMPC. Initial coordinates for DMPC MD simulations (1-4). No water 687
molecules and KCl are included. Format is PDB for first configuration and compressed 688
(Bzip2) XYZ format for the other configurations. 689
S3 File. Mg/DMPC. Initial coordinates for Mg/DMPC MD simulations (1-3). No 690
water molecules and KCl are included. Format is the same as for DMPC. 691
S4 File. Aβ/DMPC. Initial coordinates for Aβ/DMPC CMD simulations (1-10). 692
No water molecules and KCl are included. Format is the same as for DMPC. 693
January 14, 2020 22/29
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S5 File. Cu-Aβ/DMPC. Initial coordinates for Cu-Aβ/DMPC CMD simulations 694
(1-10). No water molecules and KCl are included. Format is the same as for DMPC. 695
S6 File. Aβ/DMPC. Initial coordinates for Aβ/DMPC REMD simulations (1-56). 696
No water molecules and KCl are included. Format is the same as for DMPC. 697
S7 File. Cu-Aβ/DMPC. Initial coordinates for Cu-Aβ/DMPC REMD simulations 698
(1-56). No water molecules and KCl are included. Format is the same as for DMPC. 699
Acknowledgments 700
The work was supported by: Narodowe Centrum Nauki in Poland (grant n. 701
2015/19/B/ST4/02721); Department of Science and Technology (Ho Chi Minh City, 702
Vietnam); PLGrid Infrastructure (Poland); the bilateral project Cnr(I)-PAN(PL) “The 703
role of copper ions in neurodegeneration: molecular models”. 704
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